TL/H/5671
ADC0801/ADC0802/ADC0803/ADC0804/ADC0805
8-Bit mP Compatible A/D Converters
December 1994
ADC0801/ADC0802/ADC0803/ADC0804/ADC0805
8-Bit mP Compatible A/D Converters
General Description
The ADC0801, ADC0802, ADC0803, ADC0804 and
ADC0805 are CMOS 8-bit successive approximation A/D
converters that use a differential potentiometric ladderÐ
similar to the 256R products. These converters are de-
signed to allow operation with the NSC800 and INS8080A
derivative control bus with TRI-STATEÉoutput latches di-
rectly driving the data bus. These A/Ds appear like memory
locations or I/O ports to the microprocessor and no inter-
facing logic is needed.
Differential analog voltage inputs allow increasing the com-
mon-mode rejection and offsetting the analog zero input
voltage value. In addition, the voltage reference input can
be adjusted to allow encoding any smaller analog voltage
span to the full 8 bits of resolution.
Features
YCompatible with 8080 mP derivativesÐno interfacing
logic needed - access time - 135 ns
YEasy interface to all microprocessors, or operates
‘‘stand alone’’
YDifferential analog voltage inputs
YLogic inputs and outputs meet both MOS and TTL volt-
age level specifications
YWorks with 2.5V (LM336) voltage reference
YOn-chip clock generator
Y0V to 5V analog input voltage range with single 5V
supply
YNo zero adjust required
Y0.3×standard width 20-pin DIP package
Y20-pin molded chip carrier or small outline package
YOperates ratiometrically or with 5 VDC, 2.5 VDC, or ana-
log span adjusted voltage reference
Key Specifications
YResolution 8 bits
YTotal error g(/4 LSB, g(/2 LSB and g1 LSB
YConversion time 100 ms
Typical Applications
TL/H/5671–1
8080 Interface
TL/H/5671–31
Error Specification (Includes Full-Scale,
Zero Error, and Non-Linearity)
Part Full- VREF/2e2.500 VDC VREF/2eNo Connection
Number Scale (No Adjustments) (No Adjustments)
Adjusted
ADC0801 g(/4 LSB
ADC0802 g(/2 LSB
ADC0803 g(/2 LSB
ADC0804 g1 LSB
ADC0805 g1 LSB
TRI-STATEÉis a registered trademark of National Semiconductor Corp.
Z-80Éis a registered trademark of Zilog Corp.
C1995 National Semiconductor Corporation RRD-B30M115/Printed in U. S. A.
Absolute Maximum Ratings (Notes1&2)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales
Office/Distributors for availability and specifications.
Supply Voltage (VCC) (Note 3) 6.5V
Voltage
Logic Control Inputs b0.3V to a18V
At Other Input and Outputs b0.3V to (VCCa0.3V)
Lead Temp. (Soldering, 10 seconds)
Dual-In-Line Package (plastic) 260§C
Dual-In-Line Package (ceramic) 300§C
Surface Mount Package
Vapor Phase (60 seconds) 215§C
Infrared (15 seconds) 220§C
Storage Temperature Range b65§Ctoa
150§C
Package Dissipation at TAe25§C 875 mW
ESD Susceptibility (Note 10) 800V
Operating Ratings (Notes1&2)
Temperature Range TMINsTAsTMAX
ADC0801/02LJ, ADC0802LJ/883 b55§CsTAsa125§C
ADC0801/02/03/04LCJ b40§CsTAsa85§C
ADC0801/02/03/05LCN b40§CsTAsa85§C
ADC0804LCN 0§CsTAsa70§C
ADC0802/03/04LCV 0§CsTAsa70§C
ADC0802/03/04LCWM 0§CsTAsa70§C
Range of VCC 4.5 VDC to 6.3 VDC
Electrical Characteristics
The following specifications apply for VCCe5V
DC,T
MINsTAsTMAX and fCLKe640 kHz unless otherwise specified.
Parameter Conditions Min Typ Max Units
ADC0801: Total Adjusted Error (Note 8) With Full-Scale Adj. g(/4 LSB
(See Section 2.5.2)
ADC0802: Total Unadjusted Error (Note 8) VREF/2e2.500 VDC g(/2 LSB
ADC0803: Total Adjusted Error (Note 8) With Full-Scale Adj. g(/2 LSB
(See Section 2.5.2)
ADC0804: Total Unadjusted Error (Note 8) VREF/2e2.500 VDC g1 LSB
ADC0805: Total Unadjusted Error (Note 8) VREF/2-No Connection g1 LSB
VREF/2 Input Resistance (Pin 9) ADC0801/02/03/05 2.5 8.0 kX
ADC0804 (Note 9) 0.75 1.1 kX
Analog Input Voltage Range (Note 4) V(a)orV(
b
) Gnd– 0.05 VCCa0.05 VDC
DC Common-Mode Error Over Analog Input Voltage g(/16 g(/8 LSB
Range
Power Supply Sensitivity VCCe5V
DC g10% Over g(/16 g(/8 LSB
Allowed VIN(a) and VIN(b)
Voltage Range (Note 4)
AC Electrical Characteristics
The following specifications apply for VCCe5V
DC and TAe25§C unless otherwise specified.
Symbol Parameter Conditions Min Typ Max Units
TCConversion Time fCLKe640 kHz (Note 6) 103 114 ms
TCConversion Time (Note 5, 6) 66 73 1/fCLK
fCLK Clock Frequency VCCe5V, (Note 5) 100 640 1460 kHz
Clock Duty Cycle (Note 5) 40 60 %
CR Conversion Rate in Free-Running INTR tied to WR with 8770 9708 conv/s
Mode CSe0V
DC,f
CLKe640 kHz
tW(WR)L Width of WR Input (Start Pulse Width) CSe0V
DC (Note 7) 100 ns
tACC Access Time (Delay from Falling CLe100 pF 135 200 ns
Edge of RD to Output Data Valid)
t1H,t
0H TRI-STATE Control (Delay CLe10 pF, RLe10k 125 200 ns
from Rising Edge of RD to (See TRI-STATE Test
Hi-Z State) Circuits)
tWI,t
RI Delay from Falling Edge 300 450 ns
of WR or RD to Reset of INTR
CIN Input Capacitance of Logic 5 7.5 pF
Control Inputs
COUT TRI-STATE Output 5 7.5 pF
Capacitance (Data Buffers)
CONTROL INPUTS [Note: CLK IN (Pin 4) is the input of a Schmitt trigger circuit and is therefore specified separately]
VIN (1) Logical ‘‘1’’ Input Voltage VCCe5.25 VDC 2.0 15 VDC
(Except Pin 4 CLK IN)
2
AC Electrical Characteristics (Continued)
The following specifications apply for VCC e5VDC and TMIN sTAsTMAX, unless otherwise specified.
Symbol Parameter Conditions Min Typ Max Units
CONTROL INPUTS [Note: CLK IN (Pin 4) is the input of a Schmitt trigger circuit and is therefore specified separately]
VIN (0) Logical ‘‘0’’ Input Voltage VCCe4.75 VDC 0.8 VDC
(Except Pin 4 CLK IN)
IIN (1) Logical ‘‘1’’ Input Current VINe5V
DC 0.005 1 mADC
(All Inputs)
IIN (0) Logical ‘‘0’’ Input Current VINe0V
DC b1b0.005 mADC
(All Inputs)
CLOCK IN AND CLOCK R
VTaCLK IN (Pin 4) Positive Going 2.7 3.1 3.5 VDC
Threshold Voltage
VTbCLK IN (Pin 4) Negative 1.5 1.8 2.1 VDC
Going Threshold Voltage
VHCLK IN (Pin 4) Hysteresis 0.6 1.3 2.0 VDC
(VTa)b(VTb)
VOUT (0) Logical ‘‘0’’ CLK R Output IOe360 mA 0.4 VDC
Voltage VCCe4.75 VDC
VOUT (1) Logical ‘‘1’’ CLK R Output IOeb360 mA 2.4 VDC
Voltage VCCe4.75 VDC
DATA OUTPUTS AND INTR
VOUT (0) Logical ‘‘0’’ Output Voltage
Data Outputs IOUTe1.6 mA, VCCe4.75 VDC 0.4 VDC
INTR Output IOUTe1.0 mA, VCCe4.75 VDC 0.4 VDC
VOUT (1) Logical ‘‘1’’ Output Voltage IOeb360 mA, VCCe4.75 VDC 2.4 VDC
VOUT (1) Logical ‘‘1’’ Output Voltage IOeb10 mA, VCCe4.75 VDC 4.5 VDC
IOUT TRI-STATE Disabled Output VOUTe0V
DC b3mADC
Leakage (All Data Buffers) VOUTe5V
DC 3mADC
ISOURCE VOUT Short to Gnd, TAe25§C 4.5 6 mADC
ISINK VOUT Short to VCC,T
A
e
25§C 9.0 16 mADC
POWER SUPPLY
ICC Supply Current (Includes fCLKe640 kHz,
Ladder Current) VREF/2eNC, TAe25§C
and CSe5V
ADC0801/02/03/04LCJ/05 1.1 1.8 mA
ADC0804LCN/LCV/LCWM 1.9 2.5 mA
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. DC and AC electrical specifications do not apply when operating
the device beyond its specified operating conditions.
Note 2: All voltages are measured with respect to Gnd, unless otherwise specified. The separate A Gnd point should always be wired to the D Gnd.
Note 3: A zener diode exists, internally, from VCC to Gnd and has a typical breakdown voltage of 7 VDC.
Note 4: For VIN(b)tVIN(a) the digital output code will be 0000 0000. Two on-chip diodes are tied to each analog input (see block diagram) which will forward
conduct for analog input voltages one diode drop below ground or one diode drop greater than the VCC supply. Be careful, during testing at low VCC levels (4.5V),
as high level analog inputs (5V) can cause this input diode to conduct–especially at elevated temperatures, and cause errors for analog inputs near full-scale. The
spec allows 50 mV forward bias of either diode. This means that as long as the analog VIN does not exceed the supply voltage by more than 50 mV, the output
code will be correct. To achieve an absolute 0 VDC to5V
DC input voltage range will therefore require a minimum supply voltage of 4.950 VDC over temperature
variations, initial tolerance and loading.
Note 5: Accuracy is guaranteed at fCLK e640 kHz. At higher clock frequencies accuracy can degrade. For lower clock frequencies, the duty cycle limits can be
extended so long as the minimum clock high time interval or minimum clock low time interval is no less than 275 ns.
Note 6: With an asynchronous start pulse, up to 8 clock periods may be required before the internal clock phases are proper to start the conversion process. The
start request is internally latched, see
Figure 2
and section 2.0.
Note 7: The CS input is assumed to bracket the WR strobe input and therefore timing is dependent on the WR pulse width. An arbitrarily wide pulse width will hold
the converter in a reset mode and the start of conversion is initiated by the low to high transition of the WR pulse (see timing diagrams).
Note 8: None of these A/Ds requires a zero adjust (see section 2.5.1). To obtain zero code at other analog input voltages see section 2.5 and
Figure 5
.
Note 9: The VREF/2 pin is the center point of a two-resistor divider connected from VCC to ground. In all versions of the ADC0801, ADC0802, ADC0803, and
ADC0805, and in the ADC0804LCJ, each resistor is typically 16 kX. In all versions of the ADC0804 except the ADC0804LCJ, each resistor is typically 2.2 kX.
Note 10: Human body model, 100 pF discharged through a 1.5 kXresistor.
3
Typical Performance Characteristics
Logic Input Threshold Voltage
vs. Supply Voltage
Delay From Falling Edge of
RD to Output Data Valid
vs. Load Capacitance
CLK IN Schmitt Trip Levels
vs. Supply Voltage
fCLK vs. Clock Capacitor
Full-Scale Error vs
Conversion Time
Effect of Unadjusted Offset Error
vs. VREF/2 Voltage
Output Current vs
Temperature
Power Supply Current
vs Temperature (Note 9)
Linearity Error at Low
VREF/2 Voltages
TL/H/5671–2
4
TRI-STATE Test Circuits and Waveforms
t1H t1H,C
L
e
10 pF
tre20 ns
t0H t0H,C
L
e
10 pF
tre20 ns TL/H/5671–3
Timing Diagrams (All timing is measured from the 50% voltage points)
Output Enable and Reset INTR
Note: Read strobe must occur 8 clock periods (8/fCLK) after assertion of interrupt to guarantee reset of INTR. TL/H/5671–4
5
Typical Applications (Continued)
6800 Interface Ratiometric with Full-Scale Adjust
Note: before using caps at VIN or VREF/2,
see section 2.3.2 Input Bypass Capacitors.
Absolute with a 2.500V Reference
*For low power, see also LM385-2.5
Absolute with a 5V Reference
Zero-Shift and Span Adjust: 2VsVINs5V Span Adjust: 0VsVINs3V
TL/H/5671–5
6
Typical Applications (Continued)
Directly Converting a Low-Level Signal
VREF/2e256 mV
AmP Interfaced Comparator
For: VIN(a)lVIN(b)
OutputeFFHEX
For: VIN(a)kVIN(b)
Outpute00HEX
1 mV Resolution with mP Controlled Range
VREF/2e128 mV
1 LSBe1mV
V
DACsVINs(VDACa256 mV)
Digitizing a Current Flow
TL/H/5671–6
7
Typical Applications (Continued)
Self-Clocking Multiple A/Ds
*Use a large R value
to reduce loading
at CLK R output.
External Clocking
100 kHzsfCLKs1460 kHz
Self-Clocking in Free-Running Mode
*After power-up, a momentary grounding
of the WR input is needed to guarantee operation.
mP Interface for Free-Running A/D
Operating with ‘‘Automotive’’ Ratiometric Transducers
*VIN(b)e0.15 VCC
15% of VCCsVXDRs85% of VCC
Ratiometric with VREF/2 Forced
TL/H/5671–7
8
Typical Applications (Continued)
mP Compatible Differential-Input Comparator with Pre-Set VOS (with or without Hysteresis)
*See
Figure 5
to select R value
DB7e‘‘1’’ for VIN(a)lVIN(b)a(VREF/2)
Omit circuitry within the dotted area if
hysteresis is not needed
Handling g10V Analog Inputs
*Beckman Instruments Ý694-3-R10K resistor array
Low-Cost, mP Interfaced, Temperature-to-Digital Converter
mP Interfaced Temperature-to-Digital Converter
*Circuit values shown are for 0§CsTAsa128§C
**Can calibrate each sensor to allow easy replacement, then
A/D can be calibrated with a pre-set input voltage.
TL/H/5671–8
9
Typical Applications (Continued)
Handling g5V Analog Inputs
TL/H/5671–33
*Beckman Instruments Ý694-3-R10K resistor array
Read-Only Interface
TL/H/5671–34
mP Interfaced Comparator with Hysteresis
TL/H/5671–35
Analog Self-Test for a System
TL/H/5671–36
Protecting the Input
TL/H/5671–9
A Low-Cost, 3-Decade Logarithmic Converter
TL/H/5671–37
*LM389 transistors
A, B, C, D eLM324A quad op amp
Diodes are 1N914
10
Typical Applications (Continued)
3-Decade Logarithmic A/D Converter
Noise Filtering the Analog Input
fCe20 Hz
Uses Chebyshev implementation for steeper roll-off
unity-gain, 2nd order, low-pass filter
Adding a separate filter for each channel increases
system response time if an analog multiplexer
is used
Multiplexing Differential Inputs
Output Buffers with A/D Data Enabled
*A/D output data is updated 1 CLK period
prior to assertion of INTR
Increasing Bus Drive and/or Reducing Time on Bus
*Allows output data to set-up at falling edge of CS
TL/H/5671–10
11
Typical Applications (Continued)
Sampling an AC Input Signal
Note 1: Oversample whenever possible [keep fs l2f(b60)]to eliminate input frequency folding
(aliasing) and to allow for the skirt response of the filter.
Note 2: Consider the amplitude errors which are introduced within the passband of the filter.
70% Power Savings by Clock Gating
(Complete shutdown takes &30 seconds.)
Power Savings by A/D and VREF Shutdown
TL/H/5671–11
*Use ADC0801, 02, 03 or 05 for lowest power consumption.
Note: Logic inputs can be driven to VCC with A/D supply at zero volts.
Buffer prevents data bus from overdriving output of A/D when in shutdown mode.
12
Functional Description
1.0 UNDERSTANDING A/D ERROR SPECS
A perfect A/D transfer characteristic (staircase waveform) is
shown in
Figure 1a
. The horizontal scale is analog input
voltage and the particular points labeled are in steps of 1
LSB (19.53 mV with 2.5V tied to the VREF/2 pin). The digital
output codes that correspond to these inputs are shown as
Db1, D, and Da1. For the perfect A/D, not only will center-
value (Ab1, A, Aa1,....)analog inputs produce the cor-
rect output ditigal codes, but also each riser (the transitions
between adjacent output codes) will be located g(/2 LSB
away from each center-value. As shown, the risers are ideal
and have no width. Correct digital output codes will be pro-
vided for a range of analog input voltages that extend g(/2
LSB from the ideal center-values. Each tread (the range of
analog input voltage that provides the same digital output
code) is therefore 1 LSB wide.
Figure 1b
shows a worst case error plot for the ADC0801.
All center-valued inputs are guaranteed to produce the cor-
rect output codes and the adjacent risers are guaranteed to
be no closer to the center-value points than g(/4 LSB. In
other words, if we apply an analog input equal to the center-
value g(/4 LSB,
we guarantee
that the A/D will produce the
correct digital code. The maximum range of the position of
the code transition is indicated by the horizontal arrow and it
is guaranteed to be no more than (/2 LSB.
The error curve of
Figure 1c
shows a worst case error plot
for the ADC0802. Here we guarantee that if we apply an
analog input equal to the LSB analog voltage center-value
the A/D will produce the correct digital code.
Next to each transfer function is shown the corresponding
error plot. Many people may be more familiar with error plots
than transfer functions. The analog input voltage to the A/D
is provided by either a linear ramp or by the discrete output
steps of a high resolution DAC. Notice that the error is con-
tinuously displayed and includes the quantization uncertain-
ty of the A/D. For example the error at point 1 of
Figure 1a
is a(/2 LSB because the digital code appeared (/2 LSB in
advance of the center-value of the tread. The error plots
always have a constant negative slope and the abrupt up-
side steps are always 1 LSB in magnitude.
Transfer Function Error Plot
a) Accuracyeg0 LSB: A Perfect A/D
Transfer Function Error Plot
b) Accuracyeg(/4 LSB
Transfer Function Error Plot
c) Accuracyeg(/2 LSB TL/H/5671–12
FIGURE 1. Clarifying the Error Specs of an A/D Converter
13
Functional Description (Continued)
2.0 FUNCTIONAL DESCRIPTION
The ADC0801 series contains a circuit equivalent of the
256R network. Analog switches are sequenced by succes-
sive approximation logic to match the analog difference in-
put voltage [VIN(a)bVIN(b)]to a corresponding tap on
the R network. The most significant bit is tested first and
after 8 comparisons (64 clock cycles) a digital 8-bit binary
code (1111 1111 efull-scale) is transferred to an output
latch and then an interrupt is asserted (INTR makes a high-
to-low transition). A conversion in process can be interrupt-
ed by issuing a second start command. The device may be
operated in the free-running mode by connecting INTR to
the WR input with CSe0. To ensure start-up under all pos-
sible conditions, an external WR pulse is required during the
first power-up cycle.
On the high-to-low transition of the WR input the internal
SAR latches and the shift register stages are reset. As long
as the CS input and WR input remain low, the A/D will re-
main in a reset state.
Conversion will start from 1 to 8 clock
periods after at least one of these inputs makes a low-to-
high transition
.
A functional diagram of the A/D converter is shown in
Fig-
ure 2
. All of the package pinouts are shown and the major
logic control paths are drawn in heavier weight lines.
The converter is started by having CS and WR simulta-
neously low. This sets the start flip-flop (F/F) and the result-
ing ‘‘1’’ level resets the 8-bit shift register, resets the Inter-
rupt (INTR) F/F and inputs a ‘‘1’’ to the D flop, F/F1, which
is at the input end of the 8-bit shift register. Internal clock
signals then transfer this ‘‘1’’ to the Q output of F/F1. The
AND gate, G1, combines this ‘‘1’’ output with a clock signal
to provide a reset signal to the start F/F. If the set signal is
no longer present (either WR or CS is a ‘‘1’’) the start F/F is
reset and the 8-bit shift register then can have the ‘‘1’’
clocked in, which starts the conversion process. If the set
signal were to still be present, this reset pulse would have
no effect (both outputs of the start F/F would momentarily
be at a ‘‘1’’ level) and the 8-bit shift register would continue
to be held in the reset mode. This logic therefore allows for
wide CS and WR signals and the converter will start after at
least one of these signals returns high and the internal
clocks again provide a reset signal for the start F/F.
TL/H/5671–13
Note 1: CS shown twice for clarity.
Note 2: SAR eSuccessive Approximation Register.
FIGURE 2. Block Diagram
14
Functional Description (Continued)
After the ‘‘1’’ is clocked through the 8-bit shift register
(which completes the SAR search) it appears as the input to
the D-type latch, LATCH 1. As soon as this ‘‘1’’ is output
from the shift register, the AND gate, G2, causes the new
digital word to transfer to the TRI-STATE output latches.
When LATCH 1 is subsequently enabled, the Q output
makes a high-to-low transition which causes the INTR F/F
to set. An inverting buffer then supplies the INTR input sig-
nal.
Note that this SET control of the INTR F/F remains low for
8 of the external clock periods (as the internal clocks run at
(/8 of the frequency of the external clock). If the data output
is continuously enabled (CS and RD both held low), the
INTR output will still signal the end of conversion (by a high-
to-low transition), because the SET input can control the Q
output of the INTR F/F even though the RESET input is
constantly at a ‘‘1’’ level in this operating mode. This INTR
output will therefore stay low for the duration of the SET
signal, which is 8 periods of the external clock frequency
(assuming the A/D is not started during this interval).
When operating in the free-running or continuous conver-
sion mode (INTR pin tied to WR and CS wired lowÐsee
also section 2.8), the START F/F is SET by the high-to-low
transition of the INTR signal. This resets the SHIFT REGIS-
TER which causes the input to the D-type latch, LATCH 1,
to go low. As the latch enable input is still present, the Q
output will go high, which then allows the INTR F/F to be
RESET. This reduces the width of the resulting INTR output
pulse to only a few propagation delays (approximately 300
ns).
When data is to be read, the combination of both CS and
RD being low will cause the INTR F/F to be reset and the
TRI-STATE output latches will be enabled to provide the 8-
bit digital outputs.
2.1 Digital Control Inputs
The digital control inputs (CS,RD, and WR) meet standard
T2L logic voltage levels. These signals have been renamed
when compared to the standard A/D Start and Output En-
able labels. In addition, these inputs are active low to allow
an easy interface to microprocessor control busses. For
non-microprocessor based applications, the CS input (pin 1)
can be grounded and the standard A/D Start function is
obtained by an active low pulse applied at the WR input (pin
3) and the Output Enable function is caused by an active
low pulse at the RD input (pin 2).
2.2 Analog Differential Voltage Inputs and
Common-Mode Rejection
This A/D has additional applications flexibility due to the
analog differential voltage input. The VIN(b) input (pin 7)
can be used to automatically subtract a fixed voltage value
from the input reading (tare correction). This is also useful in
4 mA– 20 mA current loop conversion. In addition, common-
mode noise can be reduced by use of the differential input.
The time interval between sampling VIN(a) and VIN(b)is4-
(/2 clock periods. The maximum error voltage due to this
slight time difference between the input voltage samples is
given by:
DVe(MAX) e(VP)(2qf
cm)#4.5
fCLK J,
where:
DVeis the error voltage due to sampling delay
VPis the peak value of the common-mode voltage
fcm is the common-mode frequency
As an example, to keep this error to (/4 LSB (E5 mV) when
operating with a 60 Hz common-mode frequency, fcm, and
using a 640 kHz A/D clock, fCLK, would allow a peak value
of the common-mode voltage, VP, which is given by:
VPe[DVe(MAX) (fCLK)]
(2qfcm) (4.5)
or
VPe(5 c10b3) (640c103)
(6.28) (60) (4.5)
which gives
VPj1.9V.
The allowed range of analog input voltages usually places
more severe restrictions on input common-mode noise lev-
els.
An analog input voltage with a reduced span and a relatively
large zero offset can be handled easily by making use of the
differential input (see section 2.4 Reference Voltage).
2.3 Analog Inputs
2.3.1 Input Current
Normal Mode
Due to the internal switching action, displacement currents
will flow at the analog inputs. This is due to on-chip stray
capacitance to ground as shown in
Figure 3
.
TL/H/5671–14
rON of SW 1 and SW 2 j5kX
r
e
r
ON CSTRAY j5kXc12 pF e60 ns
FIGURE 3. Analog Input Impedance
15
Functional Description (Continued)
The voltage on this capacitance is switched and will result in
currents entering the VIN(a) input pin and leaving the
VIN(b) input which will depend on the analog differential
input voltage levels. These current transients occur at the
leading edge of the internal clocks. They rapidly decay and
do not cause errors
as the on-chip comparator is strobed at
the end of the clock period.
Fault Mode
If the voltage source applied to the VIN(a)orV
IN(b) pin
exceeds the allowed operating range of VCCa50 mV, large
input currents can flow through a parasitic diode to the VCC
pin. If these currents can exceed the 1 mA max allowed
spec, an external diode (1N914) should be added to bypass
this current to the VCC pin (with the current bypassed with
this diode, the voltage at the VIN(a) pin can exceed the
VCC voltage by the forward voltage of this diode).
2.3.2 Input Bypass Capacitors
Bypass capacitors at the inputs will average these charges
and cause a DC current to flow through the output resist-
ances of the analog signal sources. This charge pumping
action is worse for continuous conversions with the VIN(a)
input voltage at full-scale. For continuous conversions with
a 640 kHz clock frequency with the VIN(a) input at 5V, this
DC current is at a maximum of approximately 5 mA. There-
fore,
bypass capacitors should not be used at the analog
inputs or the V
REF
/2 pin
for high resistance sources (l1
kX). If input bypass capacitors are necessary for noise filter-
ing and high source resistance is desirable to minimize ca-
pacitor size, the detrimental effects of the voltage drop
across this input resistance, which is due to the average
value of the input current, can be eliminated with a full-scale
adjustment while the given source resistor and input bypass
capacitor are both in place. This is possible because the
average value of the input current is a precise linear func-
tion of the differential input voltage.
2.3.3 Input Source Resistance
Large values of source resistance where an input bypass
capacitor is not used,
will not cause errors
as the input cur-
rents settle out prior to the comparison time. If a low pass
filter is required in the system, use a low valued series resis-
tor (s1kX) for a passive RC section or add an op amp RC
active low pass filter. For low source resistance applica-
tions, (s1kX), a 0.1 mF bypass capacitor at the inputs will
prevent noise pickup due to series lead inductance of a long
wire. A 100Xseries resistor can be used to isolate this ca-
pacitorÐboth the R and C are placed outside the feedback
loopÐfrom the output of an op amp, if used.
2.3.4 Noise
The leads to the analog inputs (pin 6 and 7) should be kept
as short as possible to minimize input noise coupling. Both
noise and undesired digital clock coupling to these inputs
can cause system errors. The source resistance for these
inputs should, in general, be kept below 5 kX. Larger values
of source resistance can cause undesired system noise
pickup. Input bypass capacitors, placed from the analog in-
puts to ground, will eliminate system noise pickup but can
create analog scale errors as these capacitors will average
the transient input switching currents of the A/D (see sec-
tion 2.3.1.). This scale error depends on both a large source
resistance and the use of an input bypass capacitor. This
error can be eliminated by doing a full-scale adjustment of
the A/D (adjust VREF/2 for a proper full-scale readingÐsee
section 2.5.2 on Full-Scale Adjustment) with the source re-
sistance and input bypass capacitor in place.
2.4 Reference Voltage
2.4.1 Span Adjust
For maximum applications flexibility, these A/Ds have been
designed to accommodatea5V
DC, 2.5 VDC or an adjusted
voltage reference. This has been achieved in the design of
the IC as shown in
Figure 4
.
TL/H/5671–15
FIGURE 4. The VREFERENCE Design on the IC
Notice that the reference voltage for the IC is either (/2 of
the voltage applied to the VCC supply pin, or is equal to the
voltage that is externally forced at the VREF/2 pin. This al-
lows for a ratiometric voltage reference using the VCC sup-
ply, a 5 VDC reference voltage can be used for the VCC
supply or a voltage less than 2.5 VDC can be applied to the
VREF/2 input for increased application flexibility. The inter-
nal gain to the VREF/2 input is 2, making the full-scale differ-
ential input voltage twice the voltage at pin 9.
An example of the use of an adjusted reference voltage is to
accommodate a reduced spanÐor dynamic voltage range
of the analog input voltage. If the analog input voltage were
to range from 0.5 VDC to 3.5 VDC, instead of 0V to 5 VDC,
the span would be 3V as shown in
Figure 5
. With 0.5 VDC
applied to the VIN(b) pin to absorb the offset, the reference
voltage can be made equal to (/2 of the 3V span or 1.5 VDC.
The A/D now will encode the VIN(a) signal from 0.5V to 3.5
V with the 0.5V input corresponding to zero and the 3.5 VDC
input corresponding to full-scale. The full 8 bits of resolution
are therefore applied over this reduced analog input voltage
range.
16
Functional Description (Continued)
*Add if VREF/2 s1V
DC with LM358
to draw 3 mA to ground.
TL/H/5671–16
a) Analog Input Signal Example b) Accommodating an Analog Input from
0.5V (Digital Out ee00HEX) to 3.5V
(Digital OuteFFHEX)
FIGURE 5. Adapting the A/D Analog Input Voltages to Match an Arbitrary Input Signal Range
2.4.2 Reference Accuracy Requirements
The converter can be operated in a ratiometric mode or an
absolute mode. In ratiometric converter applications, the
magnitude of the reference voltage is a factor in both the
output of the source transducer and the output of the A/D
converter and therefore cancels out in the final digital output
code. The ADC0805 is specified particularly for use in ratio-
metric applications with no adjustments required. In abso-
lute conversion applications, both the initial value and the
temperature stability of the reference voltage are important
factors in the accuracy of the A/D converter. For VREF/2
voltages of 2.4 VDC nominal value, initial errors of g10
mVDC will cause conversion errors of g1 LSB due to the
gain of 2 of the VREF/2 input. In reduced span applications,
the initial value and the stability of the VREF/2 input voltage
become even more important. For example, if the span is
reduced to 2.5V, the analog input LSB voltage value is cor-
respondingly reduced from 20 mV (5V span) to 10 mV and
1 LSB at the VREF/2 input becomes 5 mV. As can be seen,
this reduces the allowed initial tolerance of the reference
voltage and requires correspondingly less absolute change
with temperature variations. Note that spans smaller than
2.5V place even tighter requirements on the initial accuracy
and stability of the reference source.
In general, the magnitude of the reference voltage will re-
quire an initial adjustment. Errors due to an improper value
of reference voltage appear as full-scale errors in the A/D
transfer function. IC voltage regulators may be used for ref-
erences if the ambient temperature changes are not exces-
sive. The LM336B 2.5V IC reference diode (from National
Semiconductor) has a temperature stability of 1.8 mV typ
(6 mV max) over 0§CsTAsa70§C. Other temperature
range parts are also available.
2.5 Errors and Reference Voltage Adjustments
2.5.1 Zero Error
The zero of the A/D does not require adjustment. If the
minimum analog input voltage value, VIN(MIN), is not ground,
a zero offset can be done. The converter can be made to
output 0000 0000 digital code for this minimum input voltage
by biasing the A/D VIN(b) input at this VIN(MIN) value (see
Applications section). This utilizes the differential mode op-
eration of the A/D.
The zero error of the A/D converter relates to the location
of the first riser of the transfer function and can be mea-
sured by grounding the VIN (b) input and applying a small
magnitude positive voltage to the VIN (a) input. Zero error
is the difference between the actual DC input voltage that is
necessary to just cause an output digital code transition
from 0000 0000 to 0000 0001 and the ideal (/2 LSB value
((/2 LSB e9.8 mV for VREF/2e2.500 VDC).
2.5.2 Full-Scale
The full-scale adjustment can be made by applying a differ-
ential input voltage that is 1(/2 LSB less than the desired
analog full-scale voltage range and then adjusting the mag-
nitude of the VREF/2 input (pin 9 or the VCC supply if pin 9 is
not used) for a digital output code that is just changing from
1111 1110 to 1111 1111.
17
Functional Description (Continued)
2.5.3 Adjusting for an Arbitrary Analog Input Voltage
Range
If the analog zero voltage of the A/D is shifted away from
ground (for example, to accommodate an analog input sig-
nal that does not go to ground) this new zero reference
should be properly adjusted first. A VIN(a) voltage that
equals this desired zero reference plus (/2 LSB (where the
LSB is calculated for the desired analog span, 1 LSBeana-
log span/256) is applied to pin 6 and the zero reference
voltage at pin 7 should then be adjusted to just obtain the
00HEX to 01HEX code transition.
The full-scale adjustment should then be made (with the
proper VIN(b) voltage applied) by forcing a voltage to the
VIN(a) input which is given by:
VIN (a)fsadjeV
MAXb1.5 Ð(VMAX bVMIN)
256 (,
where:
VMAXeThe high end of the analog input range
and
VMINethe low end (the offset zero) of the analog range.
(Both are ground referenced.)
The VREF/2 (or VCC) voltage is then adjusted to provide a
code change from FEHEX to FFHEX. This completes the ad-
justment procedure.
2.6 Clocking Option
The clock for the A/D can be derived from the CPU clock or
an external RC can be added to provide self-clocking. The
CLK IN (pin 4) makes use of a Schmitt trigger as shown in
Figure 6
.
fCLKj1
1.1 RC
Rj10 kX
TL/H/5671–17
FIGURE 6. Self-Clocking the A/D
Heavy capacitive or DC loading of the clock R pin should be
avoided as this will disturb normal converter operation.
Loads less than 50 pF, such as driving up to 7 A/D convert-
er clock inputs from a single clock R pin of 1 converter, are
allowed. For larger clock line loading, a CMOS or low power
TTL buffer or PNP input logic should be used to minimize
the loading on the clock R pin (do not use a standard TTL
buffer).
2.7 Restart During a Conversion
If the A/D is restarted (CS and WR go low and return high)
during a conversion, the converter is reset and a new con-
version is started. The output data latch is not updated if the
conversion in process is not allowed to be completed, there-
fore the data of the previous conversion remains in this
latch. The INTR output simply remains at the ‘‘1’’ level.
2.8 Continuous Conversions
For operation in the free-running mode an initializing pulse
should be used, following power-up, to ensure circuit opera-
tion. In this application, the CS input is grounded and the
WR input is tied to the INTR output. This WR and INTR
node should be momentarily forced to logic low following a
power-up cycle to guarantee operation.
2.9 Driving the Data Bus
This MOS A/D, like MOS microprocessors and memories,
will require a bus driver when the total capacitance of the
data bus gets large. Other circuitry, which is tied to the data
bus, will add to the total capacitive loading, even in TRI-
STATE (high impedance mode). Backplane bussing also
greatly adds to the stray capacitance of the data bus.
There are some alternatives available to the designer to
handle this problem. Basically, the capacitive loading of the
data bus slows down the response time, even though DC
specifications are still met. For systems operating with a
relatively slow CPU clock frequency, more time is available
in which to establish proper logic levels on the bus and
therefore higher capacitive loads can be driven (see typical
characteristics curves).
At higher CPU clock frequencies time can be extended for
I/O reads (and/or writes) by inserting wait states (8080) or
using clock extending circuits (6800).
Finally, if time is short and capacitive loading is high, exter-
nal bus drivers must be used. These can be TRI-STATE
buffers (low power Schottky such as the DM74LS240 series
is recommended) or special higher drive current products
which are designed as bus drivers. High current bipolar bus
drivers with PNP inputs are recommended.
2.10 Power Supplies
Noise spikes on the VCC supply line can cause conversion
errors as the comparator will respond to this noise. A low
inductance tantalum filter capacitor should be used close to
the converter VCC pin and values of 1 mF or greater are
recommended. If an unregulated voltage is available in the
system, a separate LM340LAZ-5.0, TO-92, 5V voltage regu-
lator for the converter (and other analog circuitry) will greatly
reduce digital noise on the VCC supply.
2.11 Wiring and Hook-Up Precautions
Standard digital wire wrap sockets are not satisfactory for
breadboarding this A/D converter. Sockets on PC boards
can be used and all logic signal wires and leads should be
grouped and kept as far away as possible from the analog
signal leads. Exposed leads to the analog inputs can cause
undesired digital noise and hum pickup, therefore shielded
leads may be necessary in many applications.
18
Functional Description (Continued)
A single point analog ground that is separate from the logic
ground points should be used. The power supply bypass
capacitor and the self-clocking capacitor (if used) should
both be returned to digital ground. Any VREF/2 bypass ca-
pacitors, analog input filter capacitors, or input signal shield-
ing should be returned to the analog ground point. A test for
proper grounding is to measure the zero error of the A/D
converter. Zero errors in excess of (/4 LSB can usually be
traced to improper board layout and wiring (see section
2.5.1 for measuring the zero error).
3.0 TESTING THE A/D CONVERTER
There are many degrees of complexity associated with test-
ing an A/D converter. One of the simplest tests is to apply a
known analog input voltage to the converter and use LEDs
to display the resulting digital output code as shown in
Fig-
ure 7
.
For ease of testing, the VREF/2 (pin 9) should be supplied
with 2.560 VDC andaV
CC supply voltage of 5.12 VDC
should be used. This provides an LSB value of 20 mV.
If a full-scale adjustment is to be made, an analog input
voltage of 5.090 VDC (5.120– 1(/2 LSB) should be applied to
the VIN(a) pin with the VIN(b) pin grounded. The value of
the VREF/2 input voltage should then be adjusted until the
digital output code is just changing from 1111 1110 to 1111
1111. This value of VREF/2 should then be used for all the
tests.
The digital output LED display can be decoded by dividing
the 8 bits into 2 hex characters, the 4 most significant (MS)
and the 4 least significant (LS). Table I shows the fractional
binary equivalent of these two 4-bit groups. By adding the
voltages obtained from the ‘‘VMS’’ and ‘‘VLS’’ columns in
Table I, the nominal value of the digital display (when
TL/H/5671–18
FIGURE 7. Basic A/D Tester
VREF/2 e2.560V) can be determined. For example, for an
output LED display of 1011 0110 or B6 (in hex), the voltage
values from the table are 3.520 a0.120 or 3.640 VDC.
These voltage values represent the center-values of a per-
fect A/D converter. The effects of quantization error have to
be accounted for in the interpretation of the test results.
For a higher speed test system, or to obtain plotted data, a
digital-to-analog converter is needed for the test set-up. An
accurate 10-bit DAC can serve as the precision voltage
source for the A/D. Errors of the A/D under test can be
expressed as either analog voltages or differences in 2 digi-
tal words.
A basic A/D tester that uses a DAC and provides the error
as an analog output voltage is shown in
Figure 8
.The2op
amps can be eliminated if a lab DVM with a numerical sub-
traction feature is available to read the difference voltage,
‘‘A– C’’, directly. The analog input voltage can be supplied
by a low frequency ramp generator and an X-Y plotter can
be used to provide analog error (Y axis) versus analog input
(X axis).
For operation with a microprocessor or a computer-based
test system, it is more convenient to present the errors digi-
tally. This can be done with the circuit of
Figure 9
, where the
output code transitions can be detected as the 10-bit DAC is
incremented. This provides (/4 LSB steps for the 8-bit A/D
under test. If the results of this test are automatically plotted
with the analog input on the X axis and the error (in LSB’s)
as the Y axis, a useful transfer function of the A/D under
test results. For acceptance testing, the plot is not neces-
sary and the testing speed can be increased by establishing
internal limits on the allowed error for each code.
4.0 MICROPROCESSOR INTERFACING
To dicuss the interface with 8080A and 6800 microproces-
sors, a common sample subroutine structure is used. The
microprocessor starts the A/D, reads and stores the results
of 16 successive conversions, then returns to the user’s
program. The 16 data bytes are stored in 16 successive
memory locations. All Data and Addresses will be given in
hexadecimal form. Software and hardware details are pro-
vided separately for each type of microprocessor.
4.1 Interfacing 8080 Microprocessor Derivatives (8048,
8085)
This converter has been designed to directly interface with
derivatives of the 8080 microprocessor. The A/D can be
mapped into memory space (using standard memory ad-
dress decoding for CS and the MEMR and MEMW strobes)
or it can be controlled as an I/O device by using the I/O R
and I/O W strobes and decoding the address bits A0
x
A7 (or address bits A8
x
A15 as they will contain the
same 8-bit address information) to obtain the CS input. Us-
ing the I/O space provides 256 additional addresses and
may allow a simpler 8-bit address decoder but the data can
only be input to the accumulator. To make use of the addi-
tional memory reference instructions, the A/D should be
mapped into memory space. An example of an A/D in I/O
space is shown in
Figure 10
.
19
Functional Description (Continued)
FIGURE 8. A/D Tester with Analog Error Output
TL/H/5671–19
FIGURE 9. Basic ‘‘Digital’’ A/D Tester
TABLE I. DECODING THE DIGITAL OUTPUT LEDs
OUTPUT VOLTAGE
FRACTIONAL BINARY VALUE FOR CENTER VALUES
HEX BINARY WITH
VREF/2e2.560 VDC
MS GROUP LS GROUP VMS GROUP*VLS GROUP*
F 1 1 1 1 15/16 15/256 4.800 0.300
E 1 1 1 0 7/8 7/128 4.480 0.280
D 1 1 0 1 13/16 13/256 4.160 0.260
C 1 1 0 0 3/4 3/64 3.840 0.240
B 1 0 1 1 11/16 11/256 3.520 0.220
A 1 0 1 0 5/8 5/128 3.200 0.200
9 1 0 0 1 9/16 9/256 2/880 0.180
8 1 0 0 0 1/2 1/32 2/560 0.160
7 0 1 1 1 7/16 7/256 2.240 0.140
6 0 1 1 0 3/8 3/128 1.920 0.120
5 0 1 0 1 5/16 2/256 1.600 0.100
4 0 1 0 0 1/4 1/64 1/280 0.080
3 0 0 1 1 3/16 3/256 0.960 0.060
2 0 0 1 0 1/8 1/128 0.640 0.040
1 0 0 0 1 1/16 1/256 0.320 0.020
00000 00
*Display OutputeVMS Group aVLS Group
20
Functional Description (Continued)
TL/H/5671–20
Note 1: *Pin numbers for the DP8228 system controller, others are INS8080A.
Note 2: Pin 23 of the INS8228 must be tied to a12V througha1kXresistor to generate the RST 7
instruction when an interrupt is acknowledged as required by the accompanying sample program.
FIGURE 10. ADC0801– INS8080A CPU Interface
SAMPLE PROGRAM FOR
FIGURE 10
ADC0801– INS8080A CPU INTERFACE
0038 C3 00 03 RST 7: JMP LD DATA
## #
## #
0100 21 00 02 START: LXI H 0200H ; HL pair will point to
; data storage locations
0103 31 00 04 RETURN: LXI SP 0400H ; Initialize stack pointer (Note 1)
0106 7D MOV A, L ; Test #of bytes entered
0107 FE OF CPI OF H ; If #416. JMP to
0109 CA 13 01 JZ CONT ; user program
010C D3 E0 OUT E0 H ; Start A/D
010E FB EI ; Enable interrupt
010F 00 LOOP: NOP ; Loop until end of
0110 C3 OF 01 JMP LOOP ; conversion
0113 #CONT: #
### #
##
(User program to #
##
process data) #
### #
### #
0300 DB E0 LD DATA: IN E0 H ; Load data into accumulator
0302 77 MOV M, A ; Store data
0303 23 INX H ; Increment storage pointer
0304 C3 03 01 JMP RETURN
Note 1: The stack pointer must be dimensioned because a RST 7 instruction pushes the PC onto the stack.
Note 2: All address used were arbitrarily chosen.
21
Functional Description (Continued)
The standard control bus signals of the 8080 CS,RDand
WR) can be directly wired to the digital control inputs of the
A/D and the bus timing requirements are met to allow both
starting the converter and outputting the data onto the data
bus. A bus driver should be used for larger microprocessor
systems where the data bus leaves the PC board and/or
must drive capacitive loads larger than 100 pF.
4.1.1 Sample 8080A CPU Interfacing Circuitry and
Program
The following sample program and associated hardware
shown in
Figure 10
may be used to input data from the
converter to the INS8080A CPU chip set (comprised of the
INS8080A microprocessor, the INS8228 system controller
and the INS8224 clock generator). For simplicity, the A/D is
controlled as an I/O device, specifically an 8-bit bi-direction-
al port located at an arbitrarily chosen port address, E0. The
TRI-STATE output capability of the A/D eliminates the need
for a peripheral interface device, however address decoding
is still required to generate the appropriate CS for the con-
verter.
It is important to note that in systems where the A/D con-
verter is 1-of-8 or less I/O mapped devices, no address
decoding circuitry is necessary. Each of the 8 address bits
(A0 to A7) can be directly used as CS inputsÐone for each
I/O device.
4.1.2 INS8048 Interface
The INS8048 interface technique with the ADC0801 series
(see
Figure 11
) is simpler than the 8080A CPU interface.
There are 24 I/O lines and three test input lines in the 8048.
With these extra I/O lines available, one of the I/O lines (bit
0 of port 1) is used as the chip select signal to the A/D, thus
eliminating the use of an external address decoder. Bus
control signals RD,WRand INT of the 8048 are tied directly
to the A/D. The 16 converted data words are stored at on-
chip RAM locations from 20 to 2F (Hex). The RD and WR
signals are generated by reading from and writing into a
dummy address, respectively. A sample interface program
is shown below.
TL/H/5671–21
FIGURE 11. INS8048 Interface
SAMPLE PROGRAM FOR
FIGURE 11
INS8048 INTERFACE
04 10 JMP 10H : Program starts at addr 10
ORG 3H
04 50 JMP 50H ; Interrupt jump vector
ORG 10H ; Main program
99 FE ANL P1, #0FEH ; Chip select
81 MOVX A, @R1 ; Read in the 1st data
; to reset the intr
89 01 START: ORL P1, Ý1 ; Set port pin high
B8 20 MOV R0, #20H ; Data address
B9 FF MOV R1, #0FFH ; Dummy address
BA 10 MOV R2, #10H ; Counter for 16 bytes
23 FF AGAIN: MOV A, #0FFH ; Set ACC for intr loop
99 FE ANL P1, #0FEH ; Send CS (bit 0 of P1)
91 MOVX @R1, A ; Send WR out
05 EN I ; Enable interrupt
96 21 LOOP: JNZ LOOP ; Wait for interrupt
EA 1B DJNZ R2, AGAIN ; If 16 bytes are read
00 NOP ; go to user’s program
00 NOP
ORG 50H
81 INDATA: MOVX A, @R1 ; Input data, CS still low
A0 MOV @R0, A ; Store in memory
18 INC R0 ; Increment storage counter
89 01 ORL P1, #1 ; Reset CS signal
27 CLR A ; Clear ACC to get out of
93 RETR ; the interrupt loop
22
Functional Description (Continued)
4.2 Interfacing the Z-80
The Z-80 control bus is slightly different from that of the
8080. General RD and WR strobes are provided and sepa-
rate memory request, MREQ, and I/O request, IORQ, sig-
nals are used which have to be combined with the general-
ized strobes to provide the equivalent 8080 signals. An ad-
vantage of operating the A/D in I/O space with the Z-80 is
that the CPU will automatically insert one wait state (the RD
and WR strobes are extended one clock period) to allow
more time for the I/O devices to respond. Logic to map the
A/D in I/O space is shown in
Figure 13
.
TL/H/5671–23
FIGURE 13. Mapping the A/D as an I/O Device
for Use with the Z-80 CPU
Additional I/O advantages exist as software DMA routines
are available and use can be made of the output data trans-
fer which exists on the upper 8 address lines (A8 to A15)
during I/O input instructions. For example, MUX channel
selection for the A/D can be accomplished with this operat-
ing mode.
4.3 Interfacing 6800 Microprocessor Derivatives
(6502, etc.)
The control bus for the 6800 microprocessor derivatives
does not use the RD and WR strobe signals. Instead it em-
ploys a single R/W line and additional timing, if needed, can
be derived fom the w2 clock. All I/O devices are memory
mapped in the 6800 system, and a special signal, VMA,
indicates that the current address is valid.
Figure 14
shows
an interface schematic where the A/D is memory mapped in
the 6800 system. For simplicity, the CS decoding is shown
using (/2 DM8092. Note that in many 6800 systems, an al-
ready decoded 4/5 line is brought out to the common bus at
pin 21. This can be tied directly to the CS pin of the A/D,
provided that no other devices are addressed at HX ADDR:
4XXX or 5XXX.
The following subroutine performs essentially the same
function as in the case of the 8080A interface and it can be
called from anywhere in the user’s program.
In
Figure 15
the ADC0801 series is interfaced to the M6800
microprocessor through (the arbitrarily chosen) Port B of the
MC6820 or MC6821 Peripheral Interface Adapter, (PIA).
Here the CS pin of the A/D is grounded since the PIA is
already memory mapped in the M6800 system and no CS
decoding is necessary. Also notice that the A/D output data
lines are connected to the microprocessor bus under pro-
gram control through the PIA and therefore the A/D RD pin
can be grounded.
A sample interface program equivalent to the previous one
is shown below
Figure 15
. The PIA Data and Control Regis-
ters of Port B are located at HEX addresses 8006 and 8007,
respectively.
5.0 GENERAL APPLICATIONS
The following applications show some interesting uses for
the A/D. The fact that one particular microprocessor is used
is not meant to be restrictive. Each of these application cir-
cuits would have its counterpart using any microprocessor
that is desired.
5.1 Multiple ADC0801 Series to MC6800 CPU Interface
To transfer analog data from several channels to a single
microprocessor system, a multiple converter scheme pre-
sents several advantages over the conventional multiplexer
single-converter approach. With the ADC0801 series, the
differential inputs allow individual span adjustment for each
channel. Furthermore, all analog input channels are sensed
simultaneously, which essentially divides the microproces-
sor’s total system servicing time by the number of channels,
since all conversions occur simultaneously. This scheme is
shown in
Figure 16
.
TL/H/5671–24
Note 1: Numbers in parentheses refer to MC6800 CPU pin out.
FIGURE 14. ADC0801-MC6800 CPU Interface
Note 2: Number or letters in brackets refer to standard M6800 system common bus code.
23
Functional Description (Continued)
SAMPLE PROGRAM FOR
FIGURE 14
ADC0801-MC6800 CPU INTERFACE
0010 DF 36 DATAIN STX TEMP2 ; Save contents of X
0012 CE 00 2C LDX #$002C ; Upon IRQ low CPU
0015 FF FF F8 STX $FFF8 ; jumps to 002C
0018 B7 50 00 STAA $5000 ; Start ADC0801
001B 0E CLI
001C 3E CONVRT WAI ; Wait for interrupt
001D DE 34 LDX TEMP1
001F 8C 02 0F CPX #$020F ; Is final data stored?
0022 27 14 BEQ ENDP
0024 B7 50 00 STAA $5000 ; Restarts ADC0801
0027 08 INX
0028 DF 34 STX TEMP1
002A 20 F0 BRA CONVRT
002C DE 34 INTRPT LDX TEMP1
002E B6 50 00 LDAA $5000 ; Read data
0031 A7 00 STAA X ; Store it at X
0033 3B RTI
0034 02 00 TEMP1 FDB $0200 ; Starting address for
; data storage
0036 00 00 TEMP2 FDB $0000
0038 CE 02 00 ENDP LDX #$0200 ; Reinitialize TEMP1
003B DF 34 STX TEMP1
003D DE 36 LDX TEMP2
003F 39 RTS ; Return from subroutine
; To user’s program
Note 1: In order for the microprocessor to service subroutines and interrupts, the stack pointer must be dimensioned in the user’s program.
TL/H/5671–25
FIGURE 15. ADC0801– MC6820 PIA Interface
24
Functional Description (Continued)
SAMPLE PROGRAM FOR
FIGURE 15
ADC0801– MC6820 PIA INTERFACE
0010 CE 00 38 DATAIN LDX #$0038 ; Upon IRQ low CPU
0013 FF FF F8 STX $FFF8 ; jumps to 0038
0016 B6 80 06 LDAA PIAORB ; Clear possible IRQ flags
0019 4F CLRA
001A B7 80 07 STAA PIACRB
001D B7 80 06 STAA PIAORB ; Set Port B as input
0020 0E CLI
0021 C6 34 LDAB #$34
0023 86 3D LDAA #$3D
0025 F7 80 07 CONVRT STAB PIACRB ; Starts ADC0801
0028 B7 80 07 STAA PIACRB
002B 3E WAI ; Wait for interrupt
002C DE 40 LDX TEMP1
002E 8C 02 0F CPX #$020F ; Is final data stored?
0031 27 0F BEQ ENDP
0033 08 INX
0034 DF 40 STX TEMP1
0036 20 ED BRA CONVRT
0038 DE 40 INTRPT LDX TEMP1
003A B6 80 06 LDAA PIAORB ; Read data in
003D A7 00 STAA X ; Store it at X
003F 3B RTI
0040 02 00 TEMP1 FDB $0200 ; Starting address for
; data storage
0042 CE 02 00 ENDP LDX #$0200 ; Reinitialize TEMP1
0045 DF 40 STX TEMP1
0047 39 RTS ; Return from subroutine
PIAORB EQU $8006 ; To user’s program
PIACRB EQU $8007
The following schematic and sample subroutine (DATA IN)
may be used to interface (up to) 8 ADC0801’s directly to the
MC6800 CPU. This scheme can easily be extended to allow
the interface of more converters. In this configuration the
converters are (arbitrarily) located at HEX address 5000 in
the MC6800 memory space. To save components, the
clock signal is derived from just one RC pair on the first
converter. This output drives the other A/Ds.
All the converters are started simultaneously with a STORE
instruction at HEX address 5000. Note that any other HEX
address of the form 5XXX will be decoded by the circuit,
pulling all the CS inputs low. This can easily be avoided by
using a more definitive address decoding scheme. All the
interrupts are ORed together to insure that all A/Ds have
completed their conversion before the microprocessor is in-
terrupted.
The subroutine, DATA IN, may be called from anywhere in
the user’s program. Once called, this routine initializes the
CPU, starts all the converters simultaneously and waits for
the interrupt signal. Upon receiving the interrupt, it reads the
converters (from HEX addresses 5000 through 5007) and
stores the data successively at (arbitrarily chosen) HEX ad-
dresses 0200 to 0207, before returning to the user’s pro-
gram. All CPU registers then recover the original data they
had before servicing DATA IN.
5.2 Auto-Zeroed Differential Transducer Amplifier
and A/D Converter
The differential inputs of the ADC0801 series eliminate the
need to perform a differential to single ended conversion for
a differential transducer. Thus, one op amp can be eliminat-
ed since the differential to single ended conversion is pro-
vided by the differential input of the ADC0801 series. In gen-
eral, a transducer preamp is required to take advantage of
the full A/D converter input dynamic range.
25
Functional Description (Continued)
TL/H/5671–26
Note 1: Numbers in parentheses refer to MC6800 CPU pin out.
Note 2: Numbers of letters in brackets refer to standard M6800 system common bus code.
FIGURE 16. Interfacing Multiple A/Ds in an MC6800 System
SAMPLE PROGRAM FOR
FIGURE 16
INTERFACING MULTIPLE A/Ds IN AN MC6800 SYSTEM
ADDRESS HEX CODE MNEMONICS COMMENTS
0010 DF 44 DATAIN STX TEMP ; Save Contents of X
0012 CE 00 2A LDX #$002A ; Upon IRQ LOW CPU
0015 FF FF F8 STX $FFF8 ; Jumps to 002A
0018 B7 50 00 STAA $5000 ; Starts all A/D’s
001B 0E CLI
001C 3E WAI ; Wait for interrupt
001D CE 50 00 LDX #$5000
0020 DF 40 STX INDEX1 ; Reset both INDEX
0022 CE 02 00 LDX #$0200 ; 1 and 2 to starting
0025 DF 42 STX INDEX2 ; addresses
0027 DE 44 LDX TEMP
0029 39 RTS ; Return from subroutine
002A DE 40 INTRPT LDX INDEX1 ; INDEX1
x
X
002C A6 00 LDAA X ; Read data in from A/D at X
002E 08 INX ; Increment X by one
002F DF 40 STX INDEX1 ; X
x
INDEX1
0031 DE 42 LDX INDEX2 ; INDEX2
x
X
26
Functional Description (Continued)
SAMPLE PROGRAM FOR
FIGURE 16
INTERFACING MULTIPLE A/Ds IN AN MC6800 SYSTEM
ADDRESS HEX CODE MNEMONICS COMMENTS
0033 A7 00 STAA X ; Store data at X
0035 8C 02 07 CPX #$0207 ; Have all A/D’s been read?
0038 27 05 BEQ RETURN ; Yes: branch to RETURN
003A 08 INX ; No: increment X by one
003B DF 42 STX INDEX2 ; X
x
INDEX2
003D 20 EB BRA INTRPT ; Branch to 002A
003F 3B RETURN RTI
0040 50 00 INDEX1 FDB $5000 ; Starting address for A/D
0042 02 00 INDEX2 FDB $0200 ; Starting address for data storage
0044 00 00 TEMP FDB $0000
Note 1: In order for the microprocessor to service subroutines and interrupts, the stack pointer must be dimensioned in the user’s program.
For amplification of DC input signals, a major system error is
the input offset voltage of the amplifiers used for the
preamp.
Figure 17
is a gain of 100 differential preamp
whose offset voltage errors will be cancelled by a zeroing
subroutine which is performed by the INS8080A microproc-
essor system. The total allowable input offset voltage error
for this preamp is only 50 mV for (/4 LSB error. This would
obviously require very precise amplifiers. The expression for
the differential output voltage of the preamp is:
VOe[VIN(a)bVIN(b)]Ð1a2R2
R1 (a
X ä YXä Y
SIGNAL GAIN
(VOS2bVOS1bVOS3gIXRX)#1a2R2
R1 J
X ä YX ä Y
DC ERROR TERM GAIN
where IXis the current through resistor RX. All of the offset
error terms can be cancelled by making gIXRXeVOS1 a
VOS3 bVOS2. This is the principle of this auto-zeroing
scheme.
The INS8080A uses the 3 I/O ports of an INS8255 Pro-
gramable Peripheral Interface (PPI) to control the auto zero-
ing and input data from the ADC0801 as shown in
Figure 18
.
The PPI is programmed for basic I/O operation (mode 0)
with Port A being an input port and Ports B and C being
output ports. Two bits of Port C are used to alternately open
or close the 2 switches at the input of the preamp. Switch
SW1 is closed to force the preamp’s differential input to be
zero during the zeroing subroutine and then opened and
SW2 is then closed for conversion of the actual differential
input signal. Using 2 switches in this manner eliminates con-
cern for the ON resistance of the switches as they must
conduct only the input bias current of the input amplifiers.
Output Port B is used as a successive approximation regis-
ter by the 8080 and the binary scaled resistors in series with
each output bit create a D/A converter. During the zeroing
subroutine, the voltage at Vxincreases or decreases as re-
quired to make the differential output voltage equal to zero.
This is accomplished by ensuring that the voltage at the
output of A1 is approximately 2.5V so that a logic ‘‘1’’ (5V)
on any output of Port B will source current into node VXthus
raising the voltage at VXand making the output differential
more negative. Conversely, a logic ‘‘0’’ (0V) will pull current
out of node VXand decrease the voltage, causing the differ-
ential output to become more positive. For the resistor val-
ues shown, VXcan move g12 mV with a resolution of 50
mV, which will null the offset error term to (/4 LSB of full-
scale for the ADC0801. It is important that the voltage levels
that drive the auto-zero resistors be constant. Also, for sym-
metry, a logic swing of 0V to 5V is convenient. To achieve
this, a CMOS buffer is used for the logic output signals of
Port B and this CMOS package is powered with a stable 5V
source. Buffer amplifier A1 is necessary so that it can
source or sink the D/A output current.
27
Functional Description (Continued)
Note 1: R2 e49.5 R1
Note 2: Switches are LMC13334 CMOS analog switches.
Note 3: The 9 resistors used in the auto-zero section can be g5% tolerance.
FIGURE 17. Gain of 100 Differential Transducer Preamp
TL/H/5671–27
FIGURE 18. Microprocessor Interface Circuitry for Differential Preamp
28
A flow chart for the zeroing subroutine is shown in
Figure
19
. It must be noted that the ADC0801 series will output an
all zero code when it converts a negative input [VIN(b)t
VIN(a)]. Also, a logic inversion exists as all of the I/O ports
are buffered with inverting gates.
Basically, if the data read is zero, the differential output volt-
age is negative, so a bit in Port B is cleared to pull VXmore
negative which will make the output more positive for the
next conversion. If the data read is not zero, the output volt-
age is positive so a bit in Port B is set to make VXmore
positive and the output more negative. This continues for 8
approximations and the differential output eventually con-
verges to within 5 mV of zero.
The actual program is given in
Figure 20
. All addresses
used are compatible with the BLC 80/10 microcomputer
system. In particular:
Port A and the ADC0801 are at port address E4
Port B is at port address E5
Port C is at port address E6
PPI control word port is at port address E7
Program Counter automatically goes to ADDR:3C3D upon
acknowledgement of an interrupt from the ADC0801
5.3 Multiple A/D Converters in a Z-80 Interrupt
Driven Mode
In data acquisition systems where more than one A/D con-
verter (or other peripheral device) will be interrupting pro-
gram execution of a microprocessor, there is obviously a
need for the CPU to determine which device requires servic-
ing.
Figure 21
and the accompanying software is a method
of determining which of 7 ADC0801 converters has com-
pleted a conversion (INTR asserted) and is requesting an
interrupt. This circuit allows starting the A/D converters in
any sequence, but will input and store valid data from the
converters with a priority sequence of A/D 1 being read first,
A/D 2 second, etc., through A/D 7 which would have the
lowest priority for data being read. Only the converters
whose INT is asserted will be read.
The key to decoding circuitry is the DM74LS373, 8-bit D
type flip-flop. When the Z-80 acknowledges the interrupt,
the program is vectored to a data input Z-80 subroutine.
This subroutine will read a peripheral status word from the
DM74LS373 which contains the logic state of the INTR out-
puts of all the converters. Each converter which initiates an
interrupt will place a logic ‘‘0’’ in a unique bit position in the
status word and the subroutine will determine the identity of
the converter and execute a data read. An identifier word
(which indicates which A/D the data came from) is stored in
the next sequential memory location above the location of
the data so the program can keep track of the identity of the
data entered.
TL/H/5671–28
FIGURE 19. Flow Chart for Auto-Zero Routine
29
3D00 3E90 MVI 90
3D02 D3E7 Out Control Port ; Program PPI
3D04 2601 MVI H 01 Auto-Zero Subroutine
3D06 7C MOV A,H
3D07 D3E6 OUT C ; Close SW1 open SW2
3D09 0680 MVI B 80 ; Initialize SAR bit pointer
3D0B 3E7F MVI A 7F ; Initialize SAR code
3D0D 4F MOV C,A Return
3D0E D3E5 OUT B ; Port B 4SAR code
3D10 31AA3D LXI SP 3DAA Start ; Dimension stack pointer
3D13 D3E4 OUT A ; Start A/D
3D15 FB IE
3D16 00 NOP Loop ; Loop until INT asserted
3D17 C3163D JMP Loop
3D1A 7A MOV A,D Auto-Zero
3D1B C600 ADI 00
3D1D CA2D3D JZ Set C ; Test A/D output data for zero
3D20 78 MOV A,B Shift B
3D21 F600 ORI 00 ; Clear carry
3D23 1F RAR ; Shift ‘1‘ in B right one place
3D24 FE00 CPI 00 ; Is B zero? If yes last
3D26 CA373D JZ Done ; approximation has been made
3D29 47 MOV B,A
3D2A C3333D JMP New C
3D2D 79 MOV A,C Set C
3D2E B0 ORA B ; Set bit in C that is in same
3D2F 4F MOV C,A ; position as ‘1‘ in B
3D30 C3203D JMP Shift B
3D33 A9 XRA C New C ; Clear bit in C that is in
3D34 C30D3D JMP Return ; same position as ‘1‘ in B
3D37 47 MOV B,A Done ; then output new SAR code.
3D38 7C MOV A,H ; Open SW1, close SW2 then
3D39 EE03 XRI 03 ; proceed with program. Preamp
3D3B D3E6 OUT C ; is now zeroed.
3D3D #Normal
#
#
Program for processing
proper data values
3C3D DBE4 IN A Read A/D Subroutine ; Read A/D data
3C3F EEFF XRI FF ; Invert data
3C41 57 MOV D,A
3C42 78 MOV A,B ; Is B Reg 40? If not stay
3C43 E6FF ANI FF ; in auto zero subroutine
3C45 C21A3D JNZ Auto-Zero
3C48 C33D3D JMP Normal
Note: All numerical values are hexadecimal representations.
FIGURE 20. Software for Auto-Zeroed Differential A/D
5.3 Multiple A/D Converters in a Z-80ÉInterrupt Driven
Mode (Continued)
The following notes apply:
1) It is assumed that the CPU automatically performs a RST
7 instruction when a valid interrupt is acknowledged (CPU
is in interrupt mode 1). Hence, the subroutine starting ad-
dress of X0038.
2) The address bus from the Z-80 and the data bus to the Z-
80 are assumed to be inverted by bus drivers.
3) A/D data and identifying words will be stored in sequen-
tial memory locations starting at the arbitrarily chosen ad-
dress X 3E00.
4) The stack pointer must be dimensioned in the main pro-
gram as the RST 7 instruction automatically pushes the
PC onto the stack and the subroutine uses an additional
6 stack addresses.
5) The peripherals of concern are mapped into I/O space
with the following port assignments:
HEX PORT ADDRESS PERIPHERAL
00 MM74C374 8-bit flip-flop
01 A/D 1
02 A/D 2
03 A/D 3
04 A/D 4
05 A/D 5
06 A/D 6
07 A/D 7
This port address also serves as the A/D identifying word in
the program.
30
TL/H/5671–29
FIGURE 21. Multiple A/Ds with Z-80 Type Microprocessor
INTERRUPT SERVICING SUBROUTINE
SOURCE
LOC OBJ CODE STATEMENT COMMENT
0038 E5 PUSH HL ; Save contents of all registers affected by
0039 C5 PUSH BC ; this subroutine.
003A F5 PUSH AF ; Assumed INT mode 1 earlier set.
003B 21 00 3E LD (HL),X3E00 ; Initialize memory pointer where data will be stored.
003E 0E 01 LD C, X01 ; C register will be port ADDR of A/D converters.
0040 D300 OUT X00, A ; Load peripheral status word into 8-bit latch.
0042 DB00 IN A, X00 ; Load status word into accumulator.
0044 47 LD B,A ; Save the status word.
0045 79 TEST LD A,C ; Test to see if the status of all A/D’s have
0046 FE 08 CP, X08 ; been checked. If so, exit subroutine
0048 CA 60 00 JPZ, DONE
004B 78 LD A,B ; Test a single bit in status word by looking for
004C 1F RRA ; a ‘1‘ to be rotated into the CARRY (an INT
004D 47 LD B,A ; is loaded as a ‘1‘). If CARRY is set then load
004E DA 5500 JPC, LOAD ; contents of A/D at port ADDR in C register.
0051 0C NEXT INC C ; If CARRY is not set, increment C register to point
0052 C3 4500 JP,TEST ; to next A/D, then test next bit in status word.
0055 ED 78 LOAD IN A, (C) ; Read data from interrupting A/D and invert
0057 EE FF XOR FF ; the data.
0059 77 LD (HL),A ; Store the data
005A 2C INC L
005B 71 LD (HL),C ; Store A/D identifier (A/D port ADDR).
005C 2C INC L
005D C3 51 00 JP,NEXT ; Test next bit in status word.
0060 F1 DONE POP AF ; Re-establish all registers as they were
0061 C1 POP BC ; before the interrupt.
0062 E1 POP HL
0063 C9 RET ; Return to original program
31
Ordering Information
TEMP RANGE 0§CTO70
§
C0
§
CTO70
§
C0
§
CTO70
§
Cb
40§CTOa
85§C
g(/4 Bit ADC0801LCN
Adjusted
ERROR g(/2 Bit ADC0802LCWM ADC0802LCV ADC0802LCN
Unadjusted
g(/2 Bit ADC0803LCWM ADC0803LCV ADC0803LCN
Adjusted
g1Bit ADC0804LCWM ADC0804LCV ADC0804LCN ADC0805LCN
Unadjusted
PACKAGE OUTLINE M20BÐSmall Outline V20AÐChip Carrier N20AÐMolded DIP
TEMP RANGE b40§CTOa
85§Cb55§CTOa
125§C
g(/4 Bit Adjusted ADC0801LCJ ADC0801LJ
ERROR g(/2 Bit Unadjusted ADC0802LCJ ADC0802LJ,
g(/2 Bit Adjusted ADC0803LCJ ADC0802LJ/883
g1Bit Unadjusted ADC0804LCJ
PACKAGE OUTLINE J20AÐCavity DIP J20AÐCavity DIP
Connection Diagrams
ADC080X
Dual-In-Line and Small Outline (SO) Packages
TL/H/5671–30
ADC080X
Molded Chip Carrier (PCC) Package
TL/H/5671–32
See Ordering Information
32
33
Physical Dimensions inches (millimeters)
Dual-In-Line Package (J)
Order Number ADC0801LJ, ADC0802LJ, ADC0801LCJ,
ADC0802LCJ, ADC0803LCJ or ADC0804LCJ
ADC0802LJ/883 or 5962-9096601MRA
NS Package Number J20A
SO Package (M)
Order Number ADC0802LCWM, ADC0803LCWM or ADC0804LCWM
NS Package Number M20B
34
Physical Dimensions inches (millimeters) (Continued)
Molded Dual-In-Line Package (N)
Order Number ADC0801LCN, ADC0802LCN,
ADC0803LCN, ADC0804LCN or ADC0805LCN
NS Package Number N20A
35
ADC0801/ADC0802/ADC0803/ADC0804/ADC0805
8-Bit mP Compatible A/D Converters
Physical Dimensions inches (millimeters) (Continued)
Molded Chip Carrier Package (V)
Order Number ADC0802LCV, ADC0803LCV or ADC0804LCV
NS Package Number V20A
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